Vibrations of Deformable Objects with Different Grasping Methods

Mykhailyshyn, Roman; Erich, Floris; Duchon, Frantisek; Virgala, Ivan; Kelemen, Michal; Xiao, Jing; Majewicz Fey, Ann; Harada, Kensuke; Domae, Yukiyasu

Empreu aquest identificador per citar o enllaçar aquest ítem: http://elartu.tntu.edu.ua/handle/lib/52533

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Camp DC	Valor	Lengua/Idioma
dc.contributor.author	Mykhailyshyn, Roman	-
dc.contributor.author	Erich, Floris	-
dc.contributor.author	Duchon, Frantisek	-
dc.contributor.author	Virgala, Ivan	-
dc.contributor.author	Kelemen, Michal	-
dc.contributor.author	Xiao, Jing	-
dc.contributor.author	Majewicz Fey, Ann	-
dc.contributor.author	Harada, Kensuke	-
dc.contributor.author	Domae, Yukiyasu	-
dc.date.accessioned	2026-06-21T13:51:23Z	-
dc.date.available	2026-06-21T13:51:23Z	-
dc.date.issued	2026-06-04	-
dc.identifier.isbn	978-617-8751-20-3	-
dc.identifier.uri	http://elartu.tntu.edu.ua/handle/lib/52533	-
dc.description.abstract	The impact of object vibrations on the capabilities of robot grasping systems is very significant. The process of vibration generation from the method of grasping, even with the same gripping device, will be very different. Therefore, the need to analyze such processes in automated robotic cells creates a gap for further research to overcome vibration or use it for useful purposes.	uk_UA
dc.format.extent	223–226	-
dc.language.iso	en	uk_UA
dc.publisher	Тернопільський національний технічний університет імені Івана Пулюя	uk_UA
dc.relation.uri	https://elartu.tntu.edu.ua/handle/lib/52140	uk_UA
dc.subject	robotics	uk_UA
dc.subject	manipulation	uk_UA
dc.subject	grasping	uk_UA
dc.subject	deformable objects	uk_UA
dc.subject	vibration	uk_UA
dc.title	Vibrations of Deformable Objects with Different Grasping Methods	uk_UA
dc.title.alternative	Вібрації Деформівних Обєктів при Різних Методах Захоплення	uk_UA
dc.type	Proceedings Book	uk_UA
dc.rights.holder	© Тернопільський національний технічний університет імені Івана Пулюя, 2026	uk_UA
dc.coverage.placename	TNTU, Ternopil, Ukraine	uk_UA
dc.subject.udc	621.865	uk_UA
dc.relation.references	1. Hinwood, D., Herath, D., & Goecke, R. (2020, August). Towards the design of a human-inspired gripper for textile manipulation. In 2020 IEEE 16th International Conference on Automation Science and Engineering (CASE) (pp. 913-920). IEEE. 2. Donaire, S., Borras, J., Alenya, G., & Torras, C. (2020). A versatile gripper for cloth manipulation. IEEE Robotics and Automation Letters, 5(4), 6520-6527. 3. Ebraheem, Y., Drean, E., & Adolphe, D. C. (2021). Universal gripper for fabrics–design, validation and integration. International Journal of Clothing Science and Technology, 33(4), 643-663. 4. Mykhailyshyn, R., Savkiv, V., Maruschak, P., & Xiao, J. (2022). A systematic review on pneumatic gripping devices for industrial robots. Transport, 37(3), 201-231. 5. Borras, J., Alenya, G., & Torras, C. (2020). A grasping-centered analysis for cloth manipulation. IEEE Transactions on Robotics, 36(3), 924-936. 6. Mykhailyshyn, R., Romancik, J., Harada, K., & Fey, A. M. (2025, August). Vibration Vanquished: Enhancing Grasping of Deformable Objects with Jet Gripper Technology. In 2025 IEEE 21st International Conference on Automation Science and Engineering (CASE) (pp. 2874-2880). IEEE. 7. Mykhailyshyn, R., Savkiv, V., Fey, A. M., & Xiao, J. (2022). Gripping device for textile materials. IEEE Transactions on Automation Science and Engineering, 20(4), 2397-2408. 8. Mykhailyshyn, R., & Xiao, J. (2022). Influence of inlet parameters on power characteristics of Bernoulli gripping devices for industrial robots. Applied Sciences, 12(14), 7074. 9. Mykhailyshyn, R., Duchoň, F., Mykhailyshyn, M., & Majewicz Fey, A. (2022). Three-dimensional printing of cylindrical nozzle elements of bernoulli gripping devices for industrial robots. Robotics, 11(6), 140. 10. Kumar, V., Fontul, M., Neves, C., & Coelho, P. J. (2025). Prototyping and characterisation of gripper technologies for stiff fabric material. IEEE Access. 11. Mykhailyshyn, R., Duchoň, F., Virgala, I., Sinčák, P. J., & Majewicz Fey, A. (2023). Optimization of outer diameter bernoulli gripper with cylindrical nozzle. Machines, 11(6), 667. 12. Li, X., Li, N., Tao, G., Liu, H., & Kagawa, T. (2015). Experimental comparison of Bernoulli gripper and vortex gripper. International Journal of Precision Engineering and Manufacturing, 16(10), 2081-2090. 13. Shi, K., & Li, X. (2018). Experimental and theoretical study of dynamic characteristics of Bernoulli gripper. Precision Engineering, 52, 323-331. 14. Dini, G., Fantoni, G., & Failli, F. (2009). Grasping leather plies by Bernoulli grippers. CIRP annals, 58(1), 21-24. 15. Mykhailyshyn, R., & Fey, A. M. (2024, June). Low-contact grasping of soft tissue using a novel vortex gripper. In 2024 International Symposium on Medical Robotics (ISMR) (pp. 1-6). IEEE. 16. Petterson, A., Ohlsson, T., Caldwell, D. G., Davis, S., Gray, J. O., & Dodd, T. J. (2010). A Bernoulli principle gripper for handling of planar and 3D (food) products. Industrial Robot: An International Journal, 37(6), 518-526. 17. Liu, D., Liang, W., Zhu, H., Teo, C. S., & Tan, K. K. (2017, July). Development of a distributed Bernoulli gripper for ultra-thin wafer handling. In 2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM) (pp. 265-270). IEEE. 18. Mykhailyshyn, R., Savkiv, V., Boyko, I., Prada, E., & Virgala, I. (2021). Substantiation of parameters of friction elements of Bernoulli grippers with a cylindrical nozzle. International Journal of Manufacturing, Materials, and Mechanical Engineering (IJMMME), 11(2), 17-39. 19. Liu, D., Wang, M., Fang, N., Cong, M., & Du, Y. (2020). Design and tests of a non-contact Bernoulli gripper for rough-surfaced and fragile objects gripping. Assembly Automation, 40(5), 735-743. 20. Mykhailyshyn, R., Fey, A. M., & Xiao, J. (2023). Finite element modeling of grasping porous materials in robotics cells. Robotica, 41(11), 3485-3500. 21. Alkis, T., Fey, A. M., & Mykhailyshyn, R. (2026, January). Robotic Integration of Pneumatic Grasping Systems for Deformable Textile Handling: Automated Characterization Approach. In 2026 IEEE/SICE International Symposium on System Integration (SII) (pp. 213-218). IEEE. 22. Mykhailyshyn, R., Fey, A. M., & Xiao, J. (2023). Toward Novel Grasping of Nonrigid Materials Through Robotic End-Effector Reorientation. IEEE/ASME Transactions on Mechatronics. 23. Mykhailyshyn, R., Lee, J., Mykhailyshyn, M., Harada, K., & Fey, A. M. (2025). Dexterous manipulation of deformable objects via pneumatic gripping: Lifting by one end. arXiv preprint arXiv:2501.05198.	uk_UA
dc.relation.referencesen	1. Hinwood, D., Herath, D., & Goecke, R. (2020, August). Towards the design of a human-inspired gripper for textile manipulation. In 2020 IEEE 16th International Conference on Automation Science and Engineering (CASE) (pp. 913-920). IEEE. 2. Donaire, S., Borras, J., Alenya, G., & Torras, C. (2020). A versatile gripper for cloth manipulation. IEEE Robotics and Automation Letters, 5(4), 6520-6527. 3. Ebraheem, Y., Drean, E., & Adolphe, D. C. (2021). Universal gripper for fabrics–design, validation and integration. International Journal of Clothing Science and Technology, 33(4), 643-663. 4. Mykhailyshyn, R., Savkiv, V., Maruschak, P., & Xiao, J. (2022). A systematic review on pneumatic gripping devices for industrial robots. Transport, 37(3), 201-231. 5. Borras, J., Alenya, G., & Torras, C. (2020). A grasping-centered analysis for cloth manipulation. IEEE Transactions on Robotics, 36(3), 924-936. 6. Mykhailyshyn, R., Romancik, J., Harada, K., & Fey, A. M. (2025, August). Vibration Vanquished: Enhancing Grasping of Deformable Objects with Jet Gripper Technology. In 2025 IEEE 21st International Conference on Automation Science and Engineering (CASE) (pp. 2874-2880). IEEE. 7. Mykhailyshyn, R., Savkiv, V., Fey, A. M., & Xiao, J. (2022). Gripping device for textile materials. IEEE Transactions on Automation Science and Engineering, 20(4), 2397-2408. 8. Mykhailyshyn, R., & Xiao, J. (2022). Influence of inlet parameters on power characteristics of Bernoulli gripping devices for industrial robots. Applied Sciences, 12(14), 7074. 9. Mykhailyshyn, R., Duchoň, F., Mykhailyshyn, M., & Majewicz Fey, A. (2022). Three-dimensional printing of cylindrical nozzle elements of bernoulli gripping devices for industrial robots. Robotics, 11(6), 140. 10. Kumar, V., Fontul, M., Neves, C., & Coelho, P. J. (2025). Prototyping and characterisation of gripper technologies for stiff fabric material. IEEE Access. 11. Mykhailyshyn, R., Duchoň, F., Virgala, I., Sinčák, P. J., & Majewicz Fey, A. (2023). Optimization of outer diameter bernoulli gripper with cylindrical nozzle. Machines, 11(6), 667. 12. Li, X., Li, N., Tao, G., Liu, H., & Kagawa, T. (2015). Experimental comparison of Bernoulli gripper and vortex gripper. International Journal of Precision Engineering and Manufacturing, 16(10), 2081-2090. 13. Shi, K., & Li, X. (2018). Experimental and theoretical study of dynamic characteristics of Bernoulli gripper. Precision Engineering, 52, 323-331. 14. Dini, G., Fantoni, G., & Failli, F. (2009). Grasping leather plies by Bernoulli grippers. CIRP annals, 58(1), 21-24. 15. Mykhailyshyn, R., & Fey, A. M. (2024, June). Low-contact grasping of soft tissue using a novel vortex gripper. In 2024 International Symposium on Medical Robotics (ISMR) (pp. 1-6). IEEE. 16. Petterson, A., Ohlsson, T., Caldwell, D. G., Davis, S., Gray, J. O., & Dodd, T. J. (2010). A Bernoulli principle gripper for handling of planar and 3D (food) products. Industrial Robot: An International Journal, 37(6), 518-526. 17. Liu, D., Liang, W., Zhu, H., Teo, C. S., & Tan, K. K. (2017, July). Development of a distributed Bernoulli gripper for ultra-thin wafer handling. In 2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM) (pp. 265-270). IEEE. 18. Mykhailyshyn, R., Savkiv, V., Boyko, I., Prada, E., & Virgala, I. (2021). Substantiation of parameters of friction elements of Bernoulli grippers with a cylindrical nozzle. International Journal of Manufacturing, Materials, and Mechanical Engineering (IJMMME), 11(2), 17-39. 19. Liu, D., Wang, M., Fang, N., Cong, M., & Du, Y. (2020). Design and tests of a non-contact Bernoulli gripper for rough-surfaced and fragile objects gripping. Assembly Automation, 40(5), 735-743. 20. Mykhailyshyn, R., Fey, A. M., & Xiao, J. (2023). Finite element modeling of grasping porous materials in robotics cells. Robotica, 41(11), 3485-3500. 21. Alkis, T., Fey, A. M., & Mykhailyshyn, R. (2026, January). Robotic Integration of Pneumatic Grasping Systems for Deformable Textile Handling: Automated Characterization Approach. In 2026 IEEE/SICE International Symposium on System Integration (SII) (pp. 213-218). IEEE. 22. Mykhailyshyn, R., Fey, A. M., & Xiao, J. (2023). Toward Novel Grasping of Nonrigid Materials Through Robotic End-Effector Reorientation. IEEE/ASME Transactions on Mechatronics. 23. Mykhailyshyn, R., Lee, J., Mykhailyshyn, M., Harada, K., & Fey, A. M. (2025). Dexterous manipulation of deformable objects via pneumatic gripping: Lifting by one end. arXiv preprint arXiv:2501.05198.	uk_UA
dc.identifier.citationen	Роман Михайлишин, Флоріс Еріх, Франтішек Духон, Іван Віргала, Міхал Келемен, Джін Cяо, Енн Маєвич Фей, Кенсуке Харада, Якіясу Домае, Вібрації Деформівних Обєктів при Різних Методах Захоплення / Михайлишин Р., Духон Ф., Михайлишин М., Келемен М., Cяо Д., Маєвич Фей Е. // Прикладна механіка. Праці ІІ Міжнародної науково-технічної конференції, - Т. : ТНТУ, 2026. - С. 223–226.	uk_UA
dc.contributor.affiliation	National Institute of Advanced Industrial Science and Technology, Japan	uk_UA
dc.contributor.affiliation	Slovak University of Technology in Bratislava, Slovak Republic	uk_UA
dc.contributor.affiliation	Kosice University of Technology, Slovak Republic	uk_UA
dc.contributor.affiliation	Worcester Polytechnic Institute, United States of America	uk_UA
dc.contributor.affiliation	The University of Texas at Austin, United States of America	uk_UA
dc.contributor.affiliation	The University of Osaka, Japan	uk_UA
dc.coverage.country	UA	uk_UA
dc.identifier.citation2015	Mykhailyshyn, R., Erich, F., Duchon, F., Virgala, I., Kelemen, M., Jing, X., Majewicz Fey, A., Harada, K., & Domae, Y. (2026). Influence of Frictional Properties of Conveyor Systems on the Process of Robotic Manipulation of Flexible Objects. Proceedings of the 2nd International Scientific and Technical Conference “Applied Mechanics”, 223-226.	uk_UA
dc.identifier.citationenAPA	Mykhailyshyn, R., Erich, F., Duchon, F., Virgala, I., Kelemen, M., Jing, X., Majewicz Fey, A., Harada, K., & Domae, Y. (2026). Influence of Frictional Properties of Conveyor Systems on the Process of Robotic Manipulation of Flexible Objects. Proceedings of the 2nd International Scientific and Technical Conference “Applied Mechanics”, 223-226.	uk_UA
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